6533b871fe1ef96bd12d25a8

RESEARCH PRODUCT

Monte Carlo Test of the Classical Theory for Heterogeneous Nucleation Barriers

Peter VirnauKurt BinderDavid Winter

subject

PhysicsClassical theorySupersaturationCondensed matter physicsStatistical Mechanics (cond-mat.stat-mech)Monte Carlo methodNucleationGeneral Physics and AstronomyFOS: Physical sciencesContact angleLattice (order)Statistical physicsWettingNanoscopic scaleCondensed Matter - Statistical Mechanics

description

Flat walls facilitate the condensation of a supersaturated vapor: Classical theory of heterogeneous nucleation predicts that the free energy barrier $\Delta F_{\rm het}^*$ which needs to be overcome for the formation of sphere-cap shaped nucleation seeds is smaller than the barrier $\Delta F^*_{\rm hom}$ for spherical droplets in the bulk by a factor $0<f(\theta)<1$, which only depends on the contact angle $\theta$. In this letter we compute both $\Delta F^*_{\rm hom}$ and $\Delta F^*_{\rm het}$ from Monte Carlo simulations and test the theory for the lattice gas model (for which $\theta$ can be readily controlled). Even though the theory is only based on macroscopic arguments, it is shown to hold for experimentally relevant nanoscopic nucleation seeds ($20\leq\Delta F^*_{\rm hom}/k_BT\leq 200)$ if (independently estimated) line tension effects are considered.

yearjournalcountryeditionlanguage
2010-01-19
https://dx.doi.org/10.48550/arxiv.1001.3336